阅读说明：本技术 一种根据水流流速自调的分液调节装置 (Liquid separation adjusting device capable of self-adjusting according to flow velocity of water flow ) 是由 李一峰 于 2021-01-13 设计创作，主要内容包括：本发明公开了一种根据水流流速自调的分液调节装置,包括正磁极板、负磁极板和流水管,所述流水管内水平设置有水平分水板,所述水平分水板位于流水管内侧壁一端,且将流水管等分为上流动腔室和下流动腔室,所述正磁极板和负磁极板分别设置在上流动腔室对称侧壁上,所述水平分水板上设置有可以转动的水流冲击板。本发明采用水流冲击板会在a处左右摇摆运动,而在正磁极板和负磁极板形成有匀强磁场,加上水流冲击板材质为金属铜,可以做到切割磁感线运动,由于此时水流冲击板在a处做切割磁感线有效段比在b处做切割磁感线有效段短,即水流冲击板在a处做切割磁感线产生的电流比在b处做切割磁感线产生的电流小。(The invention discloses a liquid separation adjusting device capable of self-adjusting according to water flow velocity, which comprises a positive magnetic pole plate, a negative magnetic pole plate and a water flowing pipe, wherein a horizontal water dividing plate is horizontally arranged in the water flowing pipe, the horizontal water dividing plate is positioned at one end of the inner side wall of the water flowing pipe and divides the water flowing pipe into an upper flowing chamber and a lower flowing chamber in equal parts, the positive magnetic pole plate and the negative magnetic pole plate are respectively arranged on the symmetrical side wall of the upper flowing chamber, and a water flow impact plate capable of rotating is arranged on the horizontal water dividing plate. The water flow impact plate can swing left and right at the position a, uniform magnetic fields are formed on the positive magnetic pole plate and the negative magnetic pole plate, and the water flow impact plate is made of metal copper, so that the magnetic induction line cutting motion can be realized.)

1. A liquid separation adjusting device capable of self-adjusting according to water flow velocity comprises a positive magnetic pole plate (3), a negative magnetic pole plate (4) and a water flow pipe (1), and is characterized in that a horizontal water diversion plate (2) is horizontally arranged in the water flow pipe (1), the horizontal water diversion plate (2) is positioned at one end of the inner side wall of the water flow pipe (1) and equally divides the water flow pipe (1) into an upper flow chamber and a lower flow chamber, the positive magnetic pole plate (3) and the negative magnetic pole plate (4) are respectively arranged on the symmetrical side walls of the upper flow chamber, a rotatable water flow impact plate (6) is arranged on the horizontal water diversion plate (2), a rotating groove (18) is formed in the top of the horizontal water diversion plate (2), the water flow impact plate (6) rotates in the rotating groove (18) in the top of the horizontal water diversion plate (2) through a rotating shaft (5), and a fixing ring is arranged on the outer, the outer side wall of the rotating shaft (5) is sleeved with a clockwork spring (19), two ends of the clockwork spring (19) are respectively fixedly connected with a fixing ring and the bottom of a rotating groove (18), the top and the bottom of the rotating shaft (5) are respectively provided with a first metal contact (7) and a second metal contact (8), a circular groove is formed in the inner side wall of the lower flowing chamber, a circular groove is formed in the circular groove (11), the top and the bottom of the circular groove (11) are respectively provided with a third metal contact (9) and a fourth metal contact (10), the first metal contact (7) at the top of the rotating shaft (5) and the second metal contact (8) at the bottom of the rotating shaft (5) are respectively connected with the fourth metal contact (10) at the bottom of the circular groove (11) and the third metal contact (9) at the top of the circular groove (11) through connecting wires (17), and movable strips (12) capable of sliding are symmetrically arranged in the circular groove, two be provided with between activity strip (12) and be used for buffer spring (16) of buffering, activity strip (12) are provided with the elasticity that is used for blocking water film (13) with the relative one side of ring channel, activity strip (12) both ends one side of carrying on the back mutually all is provided with iron core stick (14), the winding of iron core stick (14) lateral wall has solenoid (15).

2. The device for regulating the distribution of liquid according to the flow rate of water flow as claimed in claim 1, wherein two solenoids (15) arranged between the third metal contact (9) and the fourth metal contact (10) are also connected through a connecting wire (17).

3. The device for regulating the distribution of liquid according to the flow rate of water flow as claimed in claim 1, wherein said buffer spring (16) is in a pulling-up state.

4. The device for adjusting the liquid separation according to the water flow velocity self-regulation according to the claim 1, wherein when the water flow impact plate (6) is not impacted, the water flow impact plate (6) is parallel to the vertical side wall of the water flowing pipe (1).

5. A device for regulating the distribution of liquid according to the flow rate of water flow as claimed in claim 1, wherein the magnetic fields generated by the current flowing through the two solenoids (15) arranged oppositely are opposite in polarity.

6. A device for regulating the distribution of liquid according to the flow rate of water flow, as claimed in claim 1, characterized in that the rotation of said rotating shaft (5) is limited by the spring (19) to be able to deflect only 90 degrees.

7. The device for regulating the distribution of liquid according to the flow rate of water flow as claimed in claim 1, wherein the water flow impact plate (6) is made of copper.

Technical Field

The invention relates to the technical field of liquid inlet regulation, in particular to a liquid separation regulating device capable of self-regulating according to the flow velocity of water flow.

Background

At present, a large amount of reaction solution is needed to be used for chemical synthesis in some industrial production processes, but liquid separation transportation needs to be carried out on solution flowing in a pipeline in the conventional solution transportation process, and the solution of the original main flow part can be divided into a plurality of branches, so that the reaction rate between an object and the solution can be accelerated, but the following problems often occur in the liquid separation process:

firstly, very easily cause the inhomogeneous of minute liquid, such phenomenon of production is mainly because solution is incessantly changed when the in-process velocity of flow of pipeline, corresponds the solution volume that same section flowed through promptly at different moments and is different, if carry out minute liquid operation according to current baffle and very easily produce the inhomogeneous phenomenon of minute liquid for later stage reaction ratio is unusual:

secondly, need use a large amount of sensors and divide liquid apparatus in the liquid process, suffer from the long-time impact of rivers, very easily cause the damage of these sensors, can cause the maintenance difficulty like this, be unfavorable for improving reaction efficiency.

Therefore, the liquid separation adjusting device capable of self-adjusting according to the flow velocity of the water flow is designed.

Disclosure of Invention

The invention aims to solve the problems that the sensors are easily damaged due to non-uniform liquid separation and long-time impact of water flow, and provides a liquid separation adjusting device capable of self-adjusting according to the flow rate of the water flow.

In order to achieve the purpose, the invention adopts the following technical scheme:

a liquid separation adjusting device capable of self-adjusting according to water flow velocity comprises a positive magnetic pole plate, a negative magnetic pole plate and a water flowing pipe, wherein a horizontal water dividing plate is horizontally arranged in the water flowing pipe and located at one end of the inner side wall of the water flowing pipe, the water flowing pipe is equally divided into an upper flowing cavity and a lower flowing cavity, the positive magnetic pole plate and the negative magnetic pole plate are respectively arranged on the symmetrical side walls of the upper flowing cavity, a water flow impact plate capable of rotating is arranged on the horizontal water dividing plate, a rotating groove is formed in the top of the horizontal water dividing plate, the water flow impact plate rotates in the rotating groove in the top of the horizontal water dividing plate through a rotating shaft, a fixing ring is arranged on the outer side wall of the rotating shaft, a clockwork spring is sleeved on the outer side wall of the rotating shaft, two ends of the clockwork spring are respectively fixedly connected, be provided with back the shape frame on the lower flow chamber indoor side wall, be provided with the ring channel in returning the shape frame, it is provided with third metal contact and fourth metal contact respectively to return shape frame top and bottom, the first metal contact at axis of rotation top and the second metal contact of axis of rotation bottom are connected with the fourth metal contact of returning the shape frame bottom and the third metal contact of returning the shape frame top through connecting wire respectively, the ring channel interior symmetry is provided with can gliding movable strip, two be provided with the buffer spring who is used for the buffering between the movable strip, movable strip and the relative one side of ring channel are provided with the elasticity that is used for blocking water and hinder the water film, the activity strip both ends are carried on the back one side mutually and all are provided with the iron core stick, the winding of iron core stick lateral wall has the solenoid.

Preferably, the two solenoids arranged between the third and fourth metal contacts are also connected by a connecting wire.

Preferably, the buffer spring is in a pulled-up state.

Preferably, when the water flow impact plate is not impacted, the water flow impact plate is parallel to the vertical side wall of the water flowing pipe.

Preferably, the magnetic fields generated by current flowing through the two oppositely disposed solenoids are opposite in polarity.

Preferably, the rotation of the rotating shaft is limited by the spring to only 90 degrees of deflection.

Preferably, the water flow impact plate is made of metal copper.

The invention has the beneficial effects that:

1. the water flow impact plate can swing left and right at the position a, uniform magnetic fields are formed on the positive magnetic pole plate and the negative magnetic pole plate, and the water flow impact plate is made of metal copper, so that the magnetic induction line cutting motion can be realized.

2. The invention adopts the magnetic fields generated by the current flowing through the solenoids arranged oppositely and the magnetism of the magnetic fields is opposite, and the current is variable, thereby ensuring that the distance between the two movable strips arranged oppositely is regulated by the current due to the repulsion of the opposite magnetic poles.

Drawings

FIG. 1 is a schematic structural diagram of a liquid-separating adjusting device capable of self-adjusting according to water flow rate according to the present invention;

FIG. 2 is a schematic structural diagram of a return frame in a liquid separation adjusting device capable of self-adjusting according to water flow velocity;

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

FIG. 4 is a side view of a self-adjusting dispensing adjustment device according to the flow rate of water flow according to the present invention;

FIG. 5 is an enlarged view of the structure at B in FIG. 1;

fig. 6 is a schematic view of a motion structure of a water flow impact plate in the liquid separation adjusting device capable of self-adjusting according to the flow velocity of water flow.

In the figure: the water flow pipe comprises a water flow pipe 1, a horizontal water diversion plate 2, a positive magnetic pole plate 3, a negative magnetic pole plate 4, a rotating shaft 5, a water flow impact plate 6, a first metal contact 7, a second metal contact 8, a third metal contact 9, a fourth metal contact 10, a returning frame 11, a movable strip 12, an elastic water-blocking film 13, an iron core rod 14, a solenoid 15, a buffer spring 16, a connecting lead 17, a rotating groove 18 and a clockwork spring 19.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-6, a liquid separation adjusting device capable of self-adjusting according to water flow velocity comprises a positive magnetic pole plate 3, a negative magnetic pole plate 4 and a water flowing pipe 1, wherein a horizontal water diversion plate 2 is horizontally arranged in the water flowing pipe 1, the horizontal water diversion plate 2 is positioned at one end of the inner side wall of the water flowing pipe 1 and divides the water flowing pipe 1 into an upper flowing chamber and a lower flowing chamber in equal parts, the positive magnetic pole plate 3 and the negative magnetic pole plate 4 are respectively arranged on the symmetrical side walls of the upper flowing chamber, a rotatable water flow impact plate 6 is arranged on the horizontal water diversion plate 2, when the water flow impact plate 6 is not impacted, the water flow impact plate 6 is parallel to the vertical side wall of the water flowing pipe 1, when the water flow velocity is small, the water flow impact plate 6 can be at a position, and the water flow velocity is changed in real time.

The water flow impact plate 6 is made of copper metal, so that cutting magnetic induction lines can move to generate induction current.

Rotation groove 18 has been seted up at 2 tops of horizontal diversion board, rivers impact plate 6 passes through rotation axis 5 and rotates in rotation groove 18 at 2 tops of horizontal diversion board, 5 lateral walls of rotation axis are provided with solid fixed ring, 5 lateral walls of rotation axis are equipped with clockwork spring 19, clockwork spring 19 both ends respectively with solid fixed ring and 18 tank bottoms fixed connection of rotation groove, the rotation of rotation axis 5 receives clockwork spring 19's restriction can only deflect 90 degrees, rivers impact plate 6 does cutting magnetic induction line effective segment in a department than do cutting magnetic induction line effective segment in b department short, the electric current that rivers impact plate 6 was cutting magnetic induction line production in a department is less than the electric current that cutting magnetic induction line produced in b department.

The top and the bottom of the rotating shaft 5 are respectively provided with a first metal contact 7 and a second metal contact 8, the inner side wall of the lower flow chamber is provided with a clip 11, the clip 11 is internally provided with an annular groove, the top and the bottom of the clip 11 are respectively provided with a third metal contact 9 and a fourth metal contact 10, the first metal contact 7 at the top of the rotating shaft 5 and the second metal contact 8 at the bottom of the rotating shaft 5 are respectively connected with the fourth metal contact 10 at the bottom of the clip 11 and the third metal contact 9 at the top of the clip 11 through a connecting wire 17, so that induced current generated on the rotating shaft 5 can be ensured to flow through the two solenoids 15 through the connecting wire 17 to generate a closed loop.

The movable strips 12 which can slide are symmetrically arranged in the annular groove, the buffer spring 16 for buffering is arranged between the two movable strips 12, the buffer spring 16 is in a pulling state, current on the solenoid 15 which is oppositely arranged always flows through and repels each other, a balancing effect can be achieved through the buffer spring 16 which is pulled up, and when the current is reduced, the repulsive force is reduced, the two movable strips 12 which are oppositely arranged can be close to each other under the action of the buffer spring 16.

An elastic water blocking film 13 for blocking water is arranged on one side of each movable strip 12 opposite to the annular groove, so that a water blocking effect can be achieved, and the solution can only flow through the two movable strips 12.

The two opposite sides of the two ends of the movable strip 12 are both provided with an iron core rod 14, the outer side wall of the iron core rod 14 is wound with a solenoid 15, and the two solenoids 15 arranged between the third metal contact 9 and the fourth metal contact 10 are also connected through a connecting lead 17.

The magnetic fields generated by the currents flowing through the two solenoids 15 arranged oppositely are opposite in magnetism, and the currents are variable, so that the distance between the two movable strips 12 arranged oppositely due to the repulsion of the opposite magnetic poles can be adjusted by the currents.

The working principle of the invention is as follows: firstly, flowing solution is led into a water flowing pipe 1, when the solution flows through a horizontal water distribution plate 2, the solution is divided into an upper flowing chamber and a lower flowing chamber, wherein a positive magnetic plate 3 and a negative magnetic plate 4 are respectively arranged on the opposite inner side walls of the flowing chambers on the horizontal water distribution plate 2, the positive magnetic plate 3 and the negative magnetic plate 4 form a uniform magnetic field, a water flow impact plate 6 can rotate in a rotating groove 18 formed in the top of the horizontal water distribution plate 2 through a rotating shaft 5, the rotation of the rotating shaft 5 is limited by a clockwork spring 19, and the water flow impact plate can only rotate in a 90-degree area formed between a and b shown in fig. 6.

Referring to fig. 6, when the water flow is small, the water flow impact plate 6 is located at the position of a, the water flow velocity is changed in real time, the water flow impact plate 6 can swing left and right at the position of a, uniform magnetic fields are formed on the positive magnetic pole plate 3 and the negative magnetic pole plate 4, the water flow impact plate 6 is made of copper metal, and cutting magnetic induction line motion can be achieved.

It should be noted that, at this time, the first metal contact 7 on the top of the rotating shaft 5 and the fourth metal contact 10 on the bottom of the clip 11, and the second metal contact 8 on the bottom of the rotating shaft 5 and the third metal contact 9 on the top of the clip 11 are connected by the connecting wire 17, and the two solenoids 15 disposed between the third metal contact 9 and the fourth metal contact 10 are also connected by the connecting wire 17, so that it can be ensured that the induced current generated on the rotating shaft 5 flows through the two solenoids 15 through the connecting wire 17 to generate a closed loop.

Then, a circular frame 11 is arranged in the lower flow chamber of the horizontal water distribution plate 2, two movable strips 12 are arranged in an annular groove formed in the circular frame 11 in a sliding manner, the two movable strips 12 are arranged oppositely, and an elastic water blocking film 13 arranged in the movable strips 12 and the annular groove can play a water blocking effect, so that the solution can only flow through the two movable strips 12.

Then, the iron core rods 14 are respectively arranged on the opposite sides of the two ends of the two oppositely arranged movable strips 12, and the solenoids 15 wound on the outer side walls of the iron core rods 14, it should be noted that the magnetic fields generated by the currents flowing through the oppositely arranged solenoids 15 are opposite in magnetism, and the currents are variable, so that the distance between the two oppositely arranged movable strips 12 due to the repulsion of the opposite magnetic poles can be adjusted by the currents.

Then, the buffer spring 16 is disposed between the two oppositely disposed movable bars 12, it should be noted that the buffer spring 16 is in a pulled-up state, and the current on the oppositely disposed solenoid 15 always flows through and repels each other, so that a balancing effect can be achieved by the pulled-up buffer spring 16, and when the current becomes smaller and the repulsive force is reduced, the two oppositely disposed movable bars 12 can approach each other under the action of the buffer spring 16.

When the water flow is small, the water flow impact plate 6 is positioned at the position a to cut a magnetic induction line, so that a small current is generated, the magnetic field repulsive force generated by the current flowing through the solenoid 15 which is oppositely arranged is small, the distance between the two movable strips 12 which are oppositely arranged is reduced by the buffer spring 16 in a pulling state, the water flow in the flow cavity below the horizontal water distribution plate 2 is limited, and more solution is enabled to flow in the flow cavity above the horizontal water distribution plate 2 to be distributed; along with the increase of the flow in the flow cavity on the horizontal water distribution plate 2, the water flow impact plate 6 can cut a magnetic induction line at the position b to generate larger current, so that the magnetic field repulsive force generated by the current flowing through the oppositely arranged solenoids 15 is larger, the water flow in the flow cavity under the horizontal water distribution plate 2 is further released, more water flows through the flow cavity under the flow, the flow distribution operation is carried out on the flow cavity under the flow, and therefore the liquid distribution can be regulated and controlled through dynamic regulation, and the flow of the liquid flowing through the flow cavity under the flow cavity is ensured to be maintained in a dynamic balance state.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.